Apparatus, system, and method for forming an elastomer lined self locking

ABSTRACT

An apparatus, system, and method that relate to a self-locking tie with one or more elastomeric features are disclosed. A strap of the self-locking tie includes one or more features that physically anchor the strap to a base of a mold during a multi-stage molding process. These features may include one or more recesses. Side walls of the one or more recesses may be sloped, as defined by anchors with undercut regions that physically engage material of the strap to prevent movement of the strap within a mold cavity of the base as the strap cools and as the strap is exposed between its formation and formation of one or more elastomeric features thereon.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of PCT Application No.PCT/US2018/058308, filed on Oct. 30, 2018 and titled APPARATUS, SYSTEM,AND METHOD FOR FORMING AN ELASTOMER LINED SELF LOCKING TIE (“the '308Application”) which claims the benefit of priority to the Oct. 30, 2017filing date of U.S. Provisional Patent Application No. 62/579,029,titled APPARATUS, SYSTEM, AND METHOD FOR FORMING AN ELASTOMER LINEDSELF-LOCKING TIE (“the '029 Provisional Application) is hereby made. Theentire disclosure of the '308 and '029 Provisional Application is herebyincorporated herein.

TECHNICAL FIELD

This disclosure relates generally to self-locking ties and moreparticularly to self-locking ties with elastomeric features. Morespecifically, this disclosure relates to methods for manufacturingself-locking ties with elastomeric features, and the features of suchself-locking ties that facilitate multi-stage molding processes.

RELATED ART

Self-locking ties have conventionally been referred to as cable ties,tie-wraps, hose ties, and zip ties. A self-locking tie is a type offastener for holding items together. A common use for self-locking tiesis to hold electrical cables, electrical wires, or hoses together. Theuse of self-locking ties is not limited to electrical cables, electricalwires, and hoses, however. Conventional self-locking ties are typicallyconstructed with smooth sides and relatively sharp corners.

The sharp corners of a conventional self-locking tie may cut into,scratch, or otherwise damage the objects it secures together. Forexample, the relatively sharp corners of a conventional self-locking tiemay damage the electrical insulators on electrical cables and wires, anddamage the walls of hoses, which may not only damage the electricalcables, electrical wires, and hoses, but may also result in seriousincidental damage.

Self-locking ties have also been used as a temporary physical restraintfor individuals. More specifically, a self-locking tie may be used tohold an individual's wrists and hands together, similar to the way inwhich handcuffs are used. When conventional self-locking ties are usedto temporarily restrain an individual's hands, the relatively sharpedges of such self-locking ties may injure the restrained individual;for example, by cutting the individual, bruising the individual, orcutting off circulation to the individual's hands. Injuries resultingfrom the use of conventional self-locking ties by law enforcementagencies as temporary physical restraints may create liability problemsfor the law enforcement agencies.

Furthermore, the hard and inflexible nature of conventional self-lockingties offers little or no friction between the self-locking ties and theobjects they encompass. In other words, conventional self-locking tiesmerely encompass objects as opposed to securely gripping them andholding them in place. This lack of friction between the self-lockingtie and the encompassed objects often results in an incomplete cincharound the encompassed objects. The self-locking tie can thereforewiggle, slide, or otherwise move around the objects it is intended tosecurely hold in place. Movement in the self-locking tie may createstresses that may cause the self-locking tie to break or otherwise fail.

SUMMARY

A self-locking tie according to this disclosure is capable of securelyencompassing objects while minimizing damage to the objects it collectsand binds together. The disclosed self-locking tie has been developed inresponse to the present state of the art, and in particular, in responseto the problems and needs in the art that have not yet been fully solvedby previously available self-locking ties.

The self-locking tie may include a strap, a locking head and one end ofthe strap, at least one cavity in the strap, and one or more elastomericfeatures. The strap may include a head end and an opposite, tapered end.The strap also includes a first surface, or front side, and an opposite,second surface, or back side. The at least one cavity may be located inone or both of the first surface and the second surface. Eachelastomeric feature may be at least partially positioned within a cavityand at least partially protrude beyond the first surface or the secondsurface of the strap. The locking head is located at the head end of thestrap and includes an orifice capable of receiving the tapered end ofthe strap and the one or more elastomeric features protruding beyond thefirst surface and/or the second surface of the strap.

The strap may include a series of ridges. Each ridge of the series mayextend across at least a portion of a width of the first surfaced of thestrap. The series of ridges may extend along at least a portion of thelength of the strap.

The at least one cavity may be located within the first surface of thestrap, laterally adjacent to the series of ridges. In some embodiments,one or more cavities may be located on opposite sides of the series ofridges. The cavities may even surround the series of ridges. In otherembodiments, one or more cavities may be located along a longitudinalcenter of the series of ridges. One or more cavities may additionally oralternatively open to a second surface of the strap. An elongatedchannel that extends along at least a portion of a length of the strapmay define one or more cavities and/or one or more cavities may bedefined by a series of voids.

Each elastomeric feature may include a cavity engaging portion and aprotruding portion. The cavity engaging portion may substantially fill acavity in the strap. The protruding portion may protrude beyond asurface of the strap to which the cavity opens. In a specificembodiment, the protruding portion of one or more elastomeric featuresmay protrude beyond the first surface of the strap and beyond the ridgeson the first surface.

A self-locking tie according to this disclosure may be manufactured in amulti-stage process. In one stage of the process, the strap may bemolded. In another stage of the process, the elastomeric features may beformed. When molding processes are used to form the elastomericfeatures, the strap may remain at least partially within a cavitydefined by a base of a mold. As the material that forms the strap cools,the strap may shrink. Accordingly, a cavity in the base of the mold mayinclude one or more features that secure anchor the strap within thebase of the mold as a first mold top, which was used to form a firstsurface of the strap, is removed and a second mold top, which will beused to form one or more elastomeric features on the first surface ofthe strap, is assembled with the base. These features are referred to asanchors. Each anchor may have a shape (e.g., a side wall oriented at anangle that defines a lip, or an overhang, etc.) that traps a portion ofthe material of the strap as the strap is molded and, thus, that holds acorresponding portion of the strap in place within the portion of themold cavity defined by the base. As material is introduced into theportion of the mold cavity defined by the base, each anchor may define arecess in a second surface of the strap. Thus, the shape of each recessmay correspond to the shape of the anchor by which it was defined. Inembodiments where the anchor includes one or more side walls oriented atan angle, the side walls defining the outer periphery of the recess maybe oriented at corresponding angles.

In addition to including one or more anchors, the base of the mold mayalso include one or more ejectors capable of forcing a correspondingportion of the strap from the portion of the mold cavity defined by thebase of the mold. In some embodiments, each ejector may comprise a pinpositioned to impact a portion of the strap that is secured to ananchor. As an example, an ejector may travel through a pathway thatextends though the height of each anchor (e.g., at its center, etc.).That pathway may be referred to as a cylinder. The force with which eachejector impacts the strap may be sufficient to cause the strap tostretch enough to release the strap from a corresponding anchor.

In some embodiments, configurations of the cylinder through each anchorin the portion of the mold cavity in the base of the mold and theejector that corresponds to that cylinder may enable the cylinder toreceive material while the strap is formed. The material received by thecylinder may form a core that protrudes from a center of the recessdefined in the second surface of the strap by an anchor; thus, athickness of the strap at the location of each core is greater than athickness of the strap at the locations of the recess that surrounds thecore. Each core may have a thickness that enables it to absorb impact ofthe ejector without damaging the strap, as might otherwise happen if theejector were to impact a recess in the second surface of the strap. Insome embodiments, each core may have sidewalls that are orientedperpendicular to a base of the recess. In other embodiments, each coremay be slanted relative to a base of the recess.

Other aspects of the disclosed subject matter, as well as features andadvantages of the disclosed subject matter, will become apparent tothose of ordinary skill in the art through consideration of the ensuingdescription, the accompanying drawings, and the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

In order that the advantages of the invention will be readilyunderstood, a description of the subject matter will be rendered byreference to specific embodiments that are illustrated in the appendeddrawings. Understanding that these drawings depict only typicalembodiments of the subject matter and are not therefore to be consideredto be limiting of its scope, the subject matter will be described andexplained with additional specificity and detail through the use of theaccompanying drawings, in which:

FIG. 1 is a perspective view illustrating one embodiment of aself-locking tie in accordance with the present subject matter;

FIG. 2 is an exploded perspective view further illustrating theself-locking tie of FIG. 1 in accordance with one embodiment of thepresent subject matter;

FIG. 3 is a top view further illustrating the self-locking tie of FIG. 1in accordance with one embodiment of the present subject matter;

FIG. 4 is a side cutaway view taken along line A-A of FIG. 3 furtherillustrating the self-locking tie in accordance with one embodiment ofthe present subject matter;

FIG. 5 is a side view further illustrating the elastomer segment of theself-locking tie of FIGS. 1-4 in accordance with another embodiment ofthe present subject matter;

FIG. 6 is a top view illustrating another embodiment of a self-lockingtie in accordance with the present subject matter;

FIG. 7A is a top view illustrating another embodiment of a strap inaccordance with the present subject matter; and

FIG. 7B is a side view illustrating one embodiment of an elastomersegment in accordance with the present subject matter;

FIG. 8 is a bottom perspective view further illustrating theself-locking tie of FIG. 1 in accordance with one embodiment of thepresent subject matter;

FIG. 9 is a top view illustrating one embodiment of a mold capable offorming a self-locking tie according to this disclosure;

FIG. 10A is a cutaway perspective view of one embodiment of an anchorand ejector in a portion of a mold cavity of a base of the mold shown inFIG. 9; and

FIG. 10B is a cutaway perspective view of another embodiment an anchorand ejector in a portion of a mold cavity of a base of the mold shown inFIG. 9.

DETAILED DESCRIPTION

FIG. 1 is a perspective view illustrating an embodiment of aself-locking tie 100 according to this disclosure. The self-locking tie100 includes a strap 102, at least one cavity 104 (see FIG. 2), anelastomer segment 106, and a locking head 108. In certain embodiments,the self-locking tie 100 also includes a series of ridges 110 thatextend across at least a portion of at least one surface of the strap102.

The strap 102, in certain embodiments, is composed of pliable materialsuch as nylon, plastic, etc. Thus, the strap 102 is bendable, allowingit to encompass one or more objects of various dimensions. The strap 102includes a head end 112 opposite from a tapered end 114. The lockinghead 108 is positioned on, coupled to, or integrally formed on the headend 112 of the strap 102.

In certain embodiments, the tapered end 114 of the strap 102 comprises asubstantially planar, pliable strap, extended in a lengthwise direction.In one embodiment, the tapered end 114 of the strap 102 can beconsidered the portion of the strap 102 extending from a positionwherein the locking head 108 is positioned on, coupled to, or otherwiseintegrally formed on the head end 112 of the strap 102.

The tapered end 114 of the strap 102 includes a first surface 116opposite from a second surface 118. In the embodiment illustrated inFIG. 1, the series of ridges 110 are depicted as extending across thefirst surface 116 of the tapered end 114 of the strap 102. In otherembodiments, the series of ridges 110 extend across the second surface118 of the strap 102. As depicted, the series of ridges 110 are formedacross most of the length of the tapered end 114 of the strap 102. Inother embodiments, the series of ridges 110 may be formed across aportion of the length of the tapered end 114 of the strap 102 that isless than the entire length of the tapered end 114 of the strap 102.

A tapered grasping tab 120 extends from the tapered end 114 of the strap102. In use, a user moves the tapered grasping tab 120 in the directionindicated by arrow 122 and into an orifice 124 in the locking head 108on the head end 112 of the strap 102 to form a loop with the strap 102.The tapered nature of the tapered grasping tab 120 facilitates insertionof the tapered grasping tab 120 into the orifice 124 in the locking head108 on the head end 112 of the strap 102. The orifice 124 in the lockinghead 108 is sized and shaped to receive the tapered end 114 of the strap102 and to receive the elastomer segment 106 which extends beyond thefirst surface 116 of the tapered end 114 of the strap 102.

FIG. 2 is an exploded perspective view illustrating the self-locking tie100 of FIG. 1 in accordance with one embodiment of the present subjectmatter. In the embodiment illustrated in FIG. 2, the elastomer segment106 has been removed from the first surface 116 of the tapered end 114of the strap 102 to more clearly illustrate the cavity 104 in the firstsurface 116 of the tapered end 114 of the strap 102.

The cavity 104, in one embodiment, is an elongated channel that extendsalong at least a portion of the length of the tapered end 114 of thestrap 102. For example, in the embodiment illustrated in FIG. 2, thecavity 104 comprises two channels 202 a and 202 b (collectively channels202) that extend along both sides of the series of ridges 110 formedacross most of the length of the tapered end 114 of the strap 102. Thechannels 202 are connected to one another by end recesses 204 a and 204b (collectively end recesses 204) at either end of the tapered end 114of the strap 102.

In other embodiments, the cavity may include channels 202 that extendalong both sides of the series of ridges 110 but which are not connectedto one another with end recesses 204. In another embodiment, thechannels 202 may extend for a length substantially less than the lengthof the tapered end 114 of the strap 102. In yet another embodiment, thecavity 104 includes a series of voids (See FIGS. 7A and 7B) locatedalong at least a portion of a length of the tapered end 114 of thestrap.

In any of the above described embodiments, at least a portion of theelastomer segment 106 is positioned within the cavity 104 to facilitatecoupling the elastomer segment 106 to the tapered end 114 of the strap102. For example, in certain embodiments, the elastomer segment 106includes a cavity engaging portion 206 which is received within thecavity 104. Disposing the cavity engaging portion 206 of the elastomersegment 106 within the cavity 104 helps to maintain a coupling betweenthe elastomer segment 106 and the tapered end 114 of the strap 102 dueto the fact that the cavity engaging portion 206 of the elastomersegment 106 is surrounded by the cavity 104 on three sides of the cavity104.

An extending portion 208 of the elastomer segment 106 extends above, orprotrudes beyond, a plane of the first surface 116 of the tapered end114 of the strap 102. The elastomer segment 106 is a flexible materialwhich may be may be comprised of materials such as silicone, rubber,thermoplastic elastomer, foam, or other materials with similarproperties. The soft and flexible quality of the elastomer segment 106enable the self-locking tie 100 to encompass one or more objects ofvarious dimension and minimize kinks and stress points thereby reducingthe self-locking tie's 100 vulnerability to wear and tear and breaking.

The friction provided by the elastomer segment 106 permits theself-locking tie 100 to grip objects more securely, holding them inplace. However, the increased friction provided by the elastomer segment106 also subjects the elastomer segment 106 to lateral forces that wouldnot otherwise be encountered. If the elastomer segment 106 were directlycoupled to the first surface 116 of the tapered end 114 of the strap102, the lateral forces may cause the elastomer segment 106 to becomeseparated from the first surface 116 of the tapered end 114 of the strap102. The cavity engaging portion 206 of the elastomer segment 106 alongwith the cavity 104 maintain the coupling between the elastomer segment106 and the first surface 116 of the tapered end 114 of the strap 102.The ability to hold objects more securely in place also enables theself-locking tie 100 to secure objects with less slack. The soft natureof the elastomer segment 106 also allows the self-locking tie 100 tosecure objects without damaging or injuring them. For example, the softnature of the elastomer segment 106 allows a user to position theself-locking tie 100 about a painted or otherwise finished objectwithout worry that the paint may become scratched or otherwise damagedby the self-locking tie 100. This is particularly true in situationswhere the self-locking tie 100 may move or vibrate when in use.

In certain embodiments, the self-locking tie 100 is formed in atwo-stage overmolding process. In the first stage, the strap 102 isformed using conventional methods known in the art. An overmold is thenpositioned on the strap 102 and a second stage is performed to mold theelastomer segment 106 onto the strap 102 with the cavity engagingportion 206 of the elastomer segment 106 positioned within the cavity104.

FIG. 3 is a top view further illustrating the self-locking tie 100 ofFIG. 1 in accordance with one embodiment of the present subject matter.As discussed above, in certain embodiments, the cavity 104 includes apair of channels 202 a and 202 b that extend along each side of theseries of ridges 110 on the first surface 116 of the tapered end 114 ofthe strap 102. The channels 202 are connected to one another by endrecesses 204 a and 204 b at either end of the tapered end 114 of thestrap 02. In the illustration depicted in FIG. 3, the channels 202 a and202 b and the end recesses 204 a and 204 b are obscured from view by theelastomer segment 106. However, one of skill in the art will recognizethat the channels 202 a and 202 b and the end recesses 204 a and 204 bare positioned below the elastomer segment 106 and have been labeled assuch.

In other embodiments, the strap 102 may include a single channel (notshown) that runs longitudinally down a center of the series of ridges110 on the first surface 116 of the tapered end 114 of the strap 102. Insuch an embodiment, the elastomer segment 106 may be a single strip ofelastomeric material that is positioned within the single channel. Oneof skill in the art will recognize that the cavity 104 may take manyother forms without departing from the spirit or essentialcharacteristic of the present disclosure.

FIG. 4 is a side cutaway view taken along line A-A of FIG. 3 furtherillustrating the self-locking tie 100 in accordance with anotherembodiment of the present subject matter. In FIG. 3, the elastomersegment 106 can be clearly seen as being positioned within channel 202 asuch that a portion (i.e., the cavity engaging portion 206) of theelastomer segment 106 is located below the first surface 116 of thetapered end 114 of the strap 102 and a second portion (i.e., extendingportion 208) extends above the plane of the first surface 116 of thetapered end 114 of the strap 102.

FIG. 5 is a side view further illustrating the elastomer segment 106 ofthe self-locking tie 100 of FIGS. 1-4 in accordance with anotherembodiment of the present subject matter. As discussed above, theelastomer segment 106 includes two portions, the cavity engaging portion206 and the extending portion 208.

In certain embodiments, the cavity engaging portion 206 of the elastomersegment 106 has a depth that is approximately the same as a depth of theextending portion 208. In other embodiments, such as in the embodimentillustrated in FIG. 5, the depth of the cavity engaging portion 206 ofthe elastomer segment 106 is smaller than the depth of the extendingportion 208. In yet another embodiment, the depth of the cavity engagingportion 206 of the elastomer segment 106 is larger than the depth of theextending portion 208.

The cavity engaging portion 206 is received within the cavity 104. Thecavity engaging portion 206 substantially fills the cavity 104 such thatthe cavity engaging portion 206 of the elastomer segment 106 issurrounded by the cavity 104 on three sides of the cavity 104.Positioning the cavity engaging portion 206 of the elastomer segment 106within the cavity 104 helps to maintain a coupling between the elastomersegment 106 and the tapered end 114 of the strap 102 due to the factthat the cavity engaging portion 206 of the elastomer segment 106 issurrounded by the cavity 104 on three sides of the cavity 104.

The extending portion 208 of the elastomer segment 106 extends above theplane of the first surface 116 of the tapered end 114 of the strap 102.The soft and flexible quality of the elastomer segment 106 enable theself-locking tie 100 to encompass one or more objects of variousdimensions and minimize kinks and stress points thereby reducing theself-locking tie's 100 vulnerability to wear, tear and breaking.

With the extending portion 208 extending beyond the plane of the firstsurface 116 of the tapered end 114 of the strap 102, the extendingportion 208 increases friction between the strap 102 and any itemsencompassed by the strap 102. The increased friction provided by theelastomer segment 106 subjects the elastomer segment 106 to lateralforces that would not otherwise be encountered. If the elastomer segment106 were directly coupled to the first surface 116 of the tapered end114 of the strap 102, the lateral forces may cause the elastomer segment106 to become separated from the first surface 116 of the tapered end114 of the strap 102.

FIG. 6 is a top view illustrating another embodiment of a self-lockingtie 600 in accordance with the present subject matter. In certainembodiments, the self-locking tie 600 is substantially similar to theself-locking tie 100 discussed above. Thus, the self-locking tie 600includes a strap 602, at least one cavity 604, an elastomer segment 606,and a locking head 608.

The strap 602, in certain embodiments, pliable material such as nylon,plastic, etc. Thus, the strap 602 is bendable to encompass one or moreobjects of various dimension. The strap 602 includes a head end 612opposite from a tapered end 614. The locking head 608 is positioned on,coupled to, or integrally formed on the head end 612 of the strap 602.

In certain embodiments, the tapered end 614 of the strap 102 comprises asubstantially planar, pliable strap extended in a lengthwise direction.In one embodiment, the tapered end 614 of the strap 602 can beconsidered the portion of the strap 602 extending from a positionwherein the locking head 608 is positioned on, coupled to, or otherwiseintegrally formed on the head end 612 of the strap 602.

The tapered end 614 of the strap 602 includes a first surface 116opposite from a second surface 618. In the embodiment illustrated inFIG. 6, a series of ridges 610 a and 610 b (collectively series ofridges 610) are depicted as extending across the first surface 616 ofthe tapered end 614 of the strap 602. The series of ridges 610 extendacross only a portion of the first surface 616 of the tapered end 614 ofthe strap 602 on opposing sides of the cavity 604. The cavity 604 islocated longitudinally along a center of a series of ridges 610. Inother embodiments, the series of ridges 610 are located on and thecavity 604 opens to the second surface 118 of the strap 102.

The elastomer segment 606 is sized and shaped to be received within thecavity 604. As with the elastomer segment 106 discussed above, theelastomer segment 606 includes a cavity engaging portion and anextending portion 620. Because the view in FIG. 6 is a top view, onlythe extending portion 620 of the elastomer segment 606 can be seen.

The cavity engaging portion and the extending portion 620 of theelastomer segment 606 of the self-locking tie 600 operate in a mannersubstantially similar to the manner in which the cavity engaging portion206 and the extending portion 208 of the self- elastomer segment 106 ofthe locking tie 100 operate. Thus, the cavity engaging portionsubstantially fills the cavity 604 and is surrounded on at least threesides to facilitate coupling between the elastomer segment 606 and thestrap 602. Similarly, the extending portion 620 of the elastomer segment606 extends beyond a plane of the first surface 616 of the tapered end614 of the strap 602.

An orifice 624 in the locking head 608 is sized and shaped to receivethe tapered end 614 of the strap 602 and to receive the elastomersegment 606 of the self-locking tie 600. Pawls 626 a and 626 b areconfigured to engage the series of ridges 610 on either side of thecavity 604 or elastomer segment 606 to maintain the tapered end 614 ofthe strap 602 at a desired position within the locking head 608.

While the embodiments depicted herein all illustrate the elastomersegment 106 or 606 and the series of ridges 110 or 610 on the firstsurface 116 or 616 of the tapered end 114 or 614 of the strap 102 or602, one of skill in in the art will recognize that the elastomersegment 106 or 606 and the series of ridges 110 or 610 may be onopposing surfaces. That is, in one embodiment, the elastomer segment 106or 606 may be positioned on the second surface 118 or 618 while theseries of ridges 110 or 610 are on the first surface 116 or 616. Ofcourse, the opposite is also true. That is, in other embodiments, theelastomer segment 106 or 606 may be positioned on the first surface 116or 616 while the series of ridges 110 or 610 are on the second surface118 or 618.

FIG. 7A is a top view illustrating another embodiment of a strap 702 inaccordance with the present subject matter. In certain embodiments,instead of including a continuous cavity, such as cavities 104 or 604discussed above, the at least one cavity 704 includes a series of voidsalong at least a portion of a tapered end 714 of the strap 702. In suchan embodiment, the elastomer segment 706 includes corresponding cavityengaging portions to substantially fill the voids comprising the atleast one cavity 704.

For example, FIG. 7B is a side view illustrating one embodiment of anelastomer segment 706 in accordance with the present subject matter. Inthe embodiment illustrated in FIG. 7B, the elastomer segment 706includes an extending portion 720 and a series of cavity engagingportions 720. Each of the cavity engaging portions 720 substantiallyfill the voids comprising the at least one cavity 704 in the strap 702.

Turning now to FIG. 8, an embodiment of a self-locking tie 100 (FIG. 1)is depicted that includes features that retain a position of its strap102 (FIG. 1) within a portion of a mold cavity as the material thatforms the strap 102 cools and as the strap 102 is exposed duringmanufacture. Although FIG. 8 includes referenced characters thatcorrespond to those used in FIG. 1, it should be noted that the featuresshown in FIG. 8 may be used with any embodiment of self-locking tieaccording to this disclosure, including, without limitation, theembodiments of self-locking ties 600 and 702 shown in FIGS. 6 and 7A,respectively.

In certain embodiments, the second surface 118 (FIG. 1) of the strap 102(FIG. 1) includes a plurality of recesses 802 a-802 e (collectivelyrecesses 802) disposed within the second surface 118 of the strap 102.The recesses 802 offer anchoring points to hold the strap 102 in placewithin the mold cavity 918 (FIG. 9) in the base 902 (FIG. 9) of a mold900 (FIG. 9) as the material of the newly formed strap 102 cools and asthe newly formed strap 102 is exposed between stages of a multi-stagemanufacturing process.

A core 804 a-804 e (collectively cores 804) is positioned within a baseof each recess 802. Each core 804 may be positioned in the center of itscorresponding recess 802. The core 804 protrudes from a bottom surface806 a-806 e (collectively bottom surfaces 806) of its correspondingrecess 802 to a position that may be substantially even with (e.g., inthe same plane as, at substantially the same elevation as, etc.) thesecond surface 118 (FIG. 1) of the strap 102 (FIG. 1). Each core 804 iscapable of being impacted by or otherwise receiving an ejectorassociated with a mold for manufacturing the self-locking tie 100 (FIG.1), which may facilitate the release of the strap 102 and theself-locking tie 100 of which the strap 102 is a part from a mold cavityonce the process of molding the self-locking tie 100 has been completed.

FIG. 9 is a top view illustrating an embodiment of a mold 900 forforming a self-locking tie 100 (FIG. 1). The mold 900 includes threeparts: a base 902; a top strap top mold 904; and an elastomer top mold906. The base 902 may include recesses and other features defining partof a mold cavity 918 for forming a corresponding part of a strap 102(FIG. 1), including the second surface 118 (FIG. 1) of the strap 102.The base 902 may also define features such as recesses 802 (FIG. 8) andcores 804 (FIG. 8) within the second surface 118 for securing the strap102 to the base 902, and may carry features that enable removal of afinished self-locking tie 100 (FIG. 1) from the base 902. The strap topmold 904 includes recesses and other features capable of defining afirst surface 116 (FIG. 1) of the strap 102. The elastomer top mold 906is capable of alignment over a newly formed strap 102 in the mold cavity918 of the base 902 to enable formation of elastomeric features (e.g.,elastomeric features 106 shown in FIG. 1, etc.) of a self-locking tie100 according to this disclosure.

The base 902 includes a mating surface 908. The mating surface 908 maybe capable of matingly receiving a mating surface 910 of the strap topmold 904 and of matingly receiving a mating surface 912 of the elastomertop mold 906.

In an embodiment of a molding process, a strap top mold 804 may beoriented over the base 902 with the mating surface of the strap top mold904 positioned against the mating surface 908 of the base 902. In thisarrangement, the base 902 and the strap 102 (FIG. 1) to mold 904 definea strap mold cavity in the shape of the strap 102. The material fromwhich the strap 102 is to be formed (e.g., nylon, etc.) is injected intothe strap mold cavity to create the strap 102, including at least onecavity 104 (FIG. 1) in the strap 102, the locking head 108 (FIG. 1), andthe series of ridges 110 (FIG. 1) of the strap 102.

The base 902 and the strap top mold 904 are then separated, and theelastomer top mold 906 is assembled with the base 902, with the matingsurface 912 of the elastomer top mold 906 and the mating surface 908 ofthe base 902 matingly receiving each other, such that the strap 102carried by the base 902 and the elastomeric top mold 906 define anelastomer mold cavity. More specifically, a portion of the elastomermold cavity defined by the elastomer top mold 906 is positioned over andis continuous with cavities (e.g., the two channels 202 a and 202 b, theend recesses 204 a and 204 b, etc.) in the strap 102 (FIG. 1). In anovermold process, an elastomeric material is then injected into theelastomer mold cavity to form the elastomeric feature(s) 106 (FIG. 1) ofthe self-locking tie 100 (FIG. 1) and to couple the elastomericfeature(s) 106 to the strap 102.

To prevent flashing and injection of the elastomeric material onto theseries of ridges 110 (FIG. 1) of the strap 102 (FIG. 1), the elastomertop mold 906 may include a series of ridges 914 configured complementaryto the series of ridges 110 of the strap 102 to mate with the series ofridges 110 when the base 902 and the elastomer top mold 906 areassembled. Mating between the series of ridges 110 of the strap 102 andthe series of ridges 914 of the elastomer top mold 906 protects theseries of ridges 110 of the strap 102 as elastomeric material isinjected into the elastomer mold cavity.

A problem may arise with mating the series of ridges 110 (FIG. 1) on thestrap 102 (FIG. 1) with the series of ridges 914 in the elastomer topmold 906. Nylon and other thermoplastic elastomers, when cooled, tend toshrink. In conventional injection molding processes, shrinkage of theitem as it cools helps to release the item from the cavity of the mold.However, in a multi-stage overmold process such as that describedherein, the strap 102 needs to remain in the portion of the mold cavity908 in the base 902 so the elastomeric features that are to be formedcan be properly aligned. Thus, shrinkage can cause misalignment of theelastomer top mold 906 with the strap 102 and/or its series of ridges110, which may damage the strap 102 or the series of ridges 110 or causeelastomeric material to be injected onto the series of ridges 110.

To counteract potential shrinkage-related issues, the base 902 mayinclude features that hold the strap 102 (FIG. 1) in place after thestrap top mold 904 is removed from the base 902 and while the elastomertop mold 906 is assembled with the base 902. Among these features is aseries of anchors 916 a-916 c (collectively anchors 916) that protrudefrom the portion of the mold cavity 918 that defines the shape of thesecond surface 118 (FIG. 1) of the strap 102. When the strap 102 ispositioned within the portion of the mold cavity 918 in the base 902,the anchors 916 and the corresponding recesses 802 (FIG. 8) they definein the second surface 118 of the strap 102 act as anchor points forsecuring the strap 102 within the mold cavity 918 of the base 902 andlimiting movement as the strap 102 shrinks.

In certain embodiments, the head-forming recess 920 of the mold cavity918 may act as an anchor point for the strap 102 (FIG. 1) as well. Giventhe relatively large locking head 108 (FIG. 1), once the strap 102 ismolded, the locking head 108 may act as an anchor point limitingmovement of the strap 102 in the direction indicated by arrow 922. Asthe strap 102 cools, each anchor 916 may engage a corresponding portionof the strap 102, securing the strap 102 in place within the mold cavity918 at discrete intervals as the strap 102 shrinks (e.g., in thedirection indicated by arrow 924, etc.). This facilitates alignment ofthe series of ridges 110 (FIG. 1) of the strap 102 with the series ofridges 914 of the elastomer top mold 906.

To facilitate removal of the strap 102 (FIG. 1) from within the moldcavity 918 of the base 902, the base 902 may include cylinders 926 a-926d (collectively cylinders 926) capable of forming the cores 804 (FIG. 8)on the strap 102. Once the overmold process has been completed and theelastomeric feature(s) 106 (FIG. 1) of the self-locking tie 100 (FIG. 1)have been formed on and coupled to the strap 102, ejectors (e.g.,ejector pins, etc.) may extend through corresponding cylinders 926 thebase 902, toward the mold cavity 918 and impact the cores 804 withsufficient force to eject the strap 102 from the mold cavity 918 of thebase 902. The cores 804 may be formed at the centers of the recesses 802(FIG. 8) in the second surface 118 (FIG. 1) of the strap 102. Having thecores 804 positioned within the recesses 802 may prevent deformation ofthe strap 102 as the strap 102 is ejected from the mold cavity 918 ofthe base 902.

FIG. 10A is a cutaway perspective view of an embodiment of an anchor 916capable of forming a recess 802 (FIG. 8) in the second surface 118(FIG. 1) of the strap 102 (FIG. 1), as well as of a pathway, or cylinder926, that extends through the anchor 916 and that is capable of forminga core 804 (FIG. 8) surrounded by the recess 802 in the second surface118 (FIG. 1) of the strap 102. Upon injection of a suitable materialinto the strap mold cavity 918, the second surface 118 of the strap 102is defined.

In certain embodiments, ejectors 1002 may be inserted through orifices1004 in the base 902 of the mold 900. Each orifice 1004 may communicatewith a cylinder 926 that extends through an anchor 916. Each ejector1002 may be inserted into and through an orifice 1004 to a position 1006that is substantially coplanar with a bottom surface 1008 of the moldcavity 918. Upon injection of a suitable material into the mold cavity918, the mold cavity 918 and the cylinder 926 may be filled with thematerial. The portions of the material that enter into cylinders 926 mayform the cores 804 within the recesses 802 in the second surface 118 ofthe strap 102.

As the material cools, the strap 102 may shrink (e.g., in a directiontowards the head 108 of the strap 102, etc.). The anchors 916 formanchor points to resist movement of the strap 102 during shrinkage ofthe strap 102 (e.g., from the tapered end 114 of the strap 102 towardsthe head end 112 of the strap 102, etc.) and hold the strap 102 withinthe mold cavity 918 of the base 902.

In the embodiment depicted by FIG. 10A, a top surface 932 of the anchor916 extends beyond, or overhangs, a bottom end 934 of the anchor 916 ina longitudinal direction opposite from the head end 112 of the strap 102(i.e., opposite from the direction indicated by arrow 1009), whereinshrinkage of the strap 102 may occur in a longitudinal direction towardsthe head end 112 of the strap 102. Thus, as the material of the strap102 cools, the anchors 916 may force the material in the directionindicated by arrow 1010. The anchors 916 may, therefore, preventmovement of the strap 102.

Sidewalls of the anchor 916 may be sloped in such a way that the anchor916 has a frustoconical shape (i.e., the shape of a cone from which thevertex has been truncated). Thus, a first side 1012 of a top surface 932of the anchor 916 may extend beyond, or overhang, a bottom end 934 ofthe anchor 916 at the same side of the anchor 916 (e.g., in alongitudinal direction opposite from the head end 112 of the strap 102,etc.). A second side 1014 of the top surface 932 of the anchor 916 mayalso extend beyond, or overhang, the bottom end 934 of the anchor 916 ina longitudinal direction towards the head end 112 of the strap 102. Insome embodiments, all of the outer edges of top surface 932 of theanchor 916 may be oriented at the same angle relative to the base of themold cavity 918 (e.g., at least 80°, but less than 90°; about 85°; about86°; about 87°; etc.). Thus, the outer edges of the top surface 932 mayoverhang the sidewalls of the anchor 916, defining a recess 1016 aroundthe anchor 916. In such an embodiment, the anchor resists movement 916of the strap in a longitudinal direction 1009 opposite from the head end112 of the strap 102 (i.e., in the direction indicated by arrow 1009)and also in a longitudinal direction towards the head end 112 of thestrap 102 (i.e., opposite the direction indicated by arrow 1009).

The strap 102, in such an embodiment, may be physically held in place bythe recess 1016 around the anchor 916. To release the strap 102 from therecess 1016, the ejector 1002 may be forced into and the cylinder 926that extends through the anchor 916 in the direction indicated by arrow1018 (e.g., by causing the sidewalls of the recess 802 in the secondside 118 of the strap 102 to stretch, etc.). Thus, the ejector 1002 mayforce the strap 102 off of the anchor 916.

FIG. 10B is a cutaway perspective view of another embodiment of ananchor 916 capable of forming a recess 802 in the second surface 118 ofthe strap 102, as well as of the cylinder 926 that extends through theanchor 916 and that is capable of forming a core 804 in the recess 802in the second surface 118 of the strap 102. Upon injection of a suitablematerial, the material fills the mold cavity 918, which defines thesecond surface 118 of the strap 102.

The anchor 916 has a slanted configuration (e.g., the appearance of aslanted column, etc., as depicted), with sloped side walls. Withoutlimitation, the anchor 916 may be tilted by up to 10° from perpendicularto the base of the mold cavity 918 (i.e., at an angle of as small asabout 80°), by about 5° from perpendicular (i.e., at an angle of about85°), by about 4° from perpendicular (i.e., at an angle of about 86°),by about 3° from perpendicular (i.e., at an angle of about 87°), etc.Thus, at a first side 1012, the top surface 932 of the anchor 916extends beyond, or overhangs, a bottom end 934 of the same side of theanchor 916. As the material of the strap 102 cools, the strap 102 mayshrink (e.g., in a direction towards the head 108 of the strap 102,etc.). The anchor 916 forms an anchor point that may resist movement ofthe strap 102 within the mold cavity 918 (e.g., from the tapered end 114of the strap 102 towards the head end 112 of the strap 102, in thedirection indicated by arrow 1009; etc.).

This orientation of the anchor 916 may permit the strap 102 to be liftedup out of the mold cavity 916 in a direction opposite from the directionindicated by arrow 1009 upon actuation of the ejector 1102. While FIG.10B illustrates a cylinder 926 and an ejector 1002 that are orientedparallel to the slant of the anchor 916, the cylinder 926 and theejector 1002 may be oriented at another angle, including perpendicularto the base of the mold cavity 918, as depicted in FIG. 10A.

Notably, the orientations, or slopes, of the sidewalls of the anchor 918and the angle at which the cylinder is oriented respectively define theorientations of side walls of the recesses 802 (FIG. 8) and the sidewalls of the cores 804 (FIG. 8) on the second side 118 of a strap 102.

Although the foregoing description provides many specifics, these shouldnot be construed as limiting the scopes of any of the appended claims,but merely as providing information pertinent to some specificembodiments that may fall within the scopes of the appended claims.Features from different embodiments may be employed in combination. Inaddition, the scopes of the appended claims may encompass otherembodiments. All additions to, deletions from, and modifications of thedisclosed subject matter that fall within the scopes of the claims areto be embraced by the claims.

What is claimed:
 1. A mold capable of forming a self-locking tie,comprising: a base, including: a mold cavity capable of defining a backside of a strap of the self-locking tie; at least one anchor protrudingfrom a bottom surface of the mold cavity, the at least one anchorcapable of physically retaining the strap in the mold cavity and offorming a recess in the back side of the strap; and at least onecylinder extending through a center of the at least one anchor, the atleast one cylinder capable of receiving material to define a coresurrounded by and protruding relative to a base of the recess in theback side of the strap; a strap top mold, including: a mold cavitycapable of defining a front side of the self-locking tie, including atleast one cavity that opens to the front side of the strap; and anelastomer top mold, including: a mold cavity capable of cooperating withthe at least one cavity to define an elastomer mold cavity over thefront side of the strap to define at least one elastomeric featuresecured within the at least one cavity and protruding from the frontside of the strap.
 2. The mold of claim 1, wherein at least one sidewall of the anchor is oriented at a non-perpendicular angle relative tothe bottom surface of the mold cavity of the base.
 3. The mold of claim2, wherein the anchor is slanted at a non-perpendicular angle relativeto the bottom surface of the mold cavity.
 4. The mold of claim 2,wherein the at least one side wall is oriented at an angle of up to 10°from perpendicular to the bottom surface of the mold cavity.
 5. The moldof claim 2, wherein the at least one side wall is oriented at an angleof about 5° from perpendicular to the bottom surface of the mold cavity.6. The mold of claim 2, wherein the at least one side wall is orientedat an angle of up to 4° from perpendicular to the bottom surface of themold cavity.
 7. The mold of claim 2, wherein the at least one side wallis oriented at an angle of up to 3° from perpendicular to the bottomsurface of the mold cavity.
 8. The mold of claim 1, further comprising:at least one ejector extendable through the cylinder through the anchor.9. A self-locking tie, comprising: a strap, including: a back side; atleast one anchor recessed in the back side; and at least one coresurrounded by and protruding relative to a base of the at least oneanchor recessed in the back side of the strap; and a front side oppositefrom the back side; and an elastomeric guard on the front side of thestrap.
 10. The self-locking tie of claim 9, wherein the front side ofthe strap includes at least one cavity.
 11. The self-locking tie ofclaim 10, wherein the elastomeric guard is secured within the at leastone cavity and protrudes from the front side of the strap.
 12. Theself-locking tie of claim 9, wherein the at least one anchor includes atleast one side wall oriented at a non-perpendicular angle relative tothe back side of the strap.
 13. The self-locking tie of claim 12,wherein the at least one core includes at least one side wall orientednonparallel to the at least one side wall of the at least one anchor.14. The self-locking tie of claim 13, wherein the at least one coreincludes at least one side wall oriented perpendicular to the back sideof the strap.
 15. The self-locking tie of claim 12, wherein the at leastone side wall of the at least one anchor is oriented at an angle of upto 10° from perpendicular to the back side of the strap.
 16. Theself-locking tie of claim 12, wherein the at least one side wall of theat least one anchor is oriented at an angle of up to 5° fromperpendicular to the back side of the strap.
 17. The self-locking tie ofclaim 12, wherein the at least one side wall of the at least one anchoris oriented at an angle of up to 4° from perpendicular to the back sideof the strap.
 18. The self-locking tie of claim 12, wherein the at leastone side wall of the at least one anchor is oriented at an angle of upto 3° from perpendicular to the back side of the strap.
 19. A method forforming a self-locking tie including at least one elastomeric feature,comprising: assembling the a mold base and a strap top mold; injecting astrap material into a strap mold cavity defined between the mold baseand the strap top mold to define a strap of the self-locking tie, atleast one anchor within the mold cavity of the mold base engaging a backside of the strap; removing the strap top mold from the mold base, thestrap being anchored within the mold cavity of the mold base by theanchor; assembling an elastomer top mold with the mold base; injectingan elastomeric material into an elastomer mold cavity defined betweenthe elastomer top mold and the strap to define at least one elastomericfeature of the self-locking tie, the at least one elastomeric featurebeing coupled to the strap; removing the elastomer top mold from themold base; and removing the self-locking tie from a mold cavity of themold base.
 20. The method of claim 19, wherein removing the self-lockingtie from the mold cavity of the mold base comprises forcing the strapoff of the at least one anchor.